Ignition by Hot Transient Jets in Confined Mixtures of Gaseous Fuels and Air

IF 1.5 Q3 ENGINEERING, CHEMICAL
Abdullah Karimi, M. Nalim
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引用次数: 3

Abstract

Ignition of a combustible mixture by a transient jet of hot reactive gas is important for safety of mines, prechamber ignition in IC engines, detonation initiation, and novel constant-volume combustors. The present work is a numerical study of the hot jet ignition process in a long constant-volume combustor (CVC) that represents a wave rotor channel. The hot jet of combustion products from a prechamber is injected through a converging nozzle into the main CVC chamber containing a premixed fuel-air mixture. Combustion in a two-dimensional analogue of the CVC chamber is modeled using a global reaction mechanism, a skeletal mechanism, or a detailed reaction mechanism for three hydrocarbon fuels: methane, propane, and ethylene. Turbulence is modeled using the two-equation SST -ω model, and each reaction rate is limited by the local turbulent mixing timescale. Hybrid turbulent-kinetic schemes using some skeletal reaction mechanisms and detailed mechanisms are good predictors of the experimental data. Shock wave traverse of the reaction zone is seen to significantly increase the overall reaction rate, likely due to compression heating, as well as baroclinic vorticity generation that stirs and mixes reactants and increases flame area. Less easily ignitable methane mixture is found to show slower initial reaction and greater dependence on shock interaction than propane and ethylene.
热瞬态射流在气体燃料和空气的密闭混合物中的点火
热反应气体的瞬态喷射点火对矿井安全、内燃机预燃室点火、爆轰起爆和新型等体积燃烧器都具有重要意义。本文对长等容燃烧室(CVC)的热射流点火过程进行了数值研究。燃烧产物的热射流从预室通过会聚喷嘴注入含有预混燃料-空气混合物的CVC主室。燃烧在二维模拟CVC室是使用一个整体的反应机制,骨架机制,或详细的反应机制为三种碳氢化合物燃料:甲烷,丙烷和乙烯建模。湍流模型采用双方程SST -ω模型,每个反应速率受局部湍流混合时间尺度的限制。采用一些骨架反应机理和详细机理的湍流-动力学混合方案对实验数据有较好的预测作用。反应区的冲击波穿越可以显著提高整体反应速率,这可能是由于压缩加热,以及斜压涡量的产生,搅拌和混合反应物并增加火焰面积。与丙烷和乙烯相比,不易点燃的甲烷混合物表现出较慢的初始反应和更大的对激波相互作用的依赖性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Combustion
Journal of Combustion ENGINEERING, CHEMICAL-
CiteScore
2.00
自引率
28.60%
发文量
8
审稿时长
20 weeks
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